CN216042131U - Light wallboard for green building - Google Patents

Abstract

The utility model discloses a light wallboard for a green building, which comprises a wallboard surface layer and a fixed block, wherein a bearing layer is arranged inside the wallboard surface layer, a sound insulation layer is arranged inside the bearing layer, a bearing rod is arranged inside the bearing layer, a convex block is arranged on one side of the bearing rod, a rotating rod is connected in the middle of the bearing rod, a concave block is arranged on one side of the bearing rod, tightening springs are connected to two sides of the convex block, a clamping block is connected to one side of each tightening spring, and the concave block is connected to one side of the fixed block. This a light wallboard for green building, this wallboard simple structure, weight is lighter, and has set up the bearing layer between wallboard top layer and puigging, plays the effect of a support protection to wallboard inside, is favorable to the wallboard to support the wallboard when external impact, prevents that the wallboard from damaging, is convenient for prolong the life of wallboard, and the inside bearing bar of bearing layer is detachable construction, is favorable to transporting in batches, is convenient for practice thrift the cost of transportation.

Description

Light wallboard for green building

Technical Field

The utility model relates to the technical field of green buildings, in particular to a light wallboard for a green building.

Background

The green building plays a vital role in the aspects of environmental pollution treatment, energy conservation, emission reduction and industrial structure adjustment in China, in the aspect of developing the green building, in the past, many countries only pay attention to steel structures and concrete structures and ignore sustainable resources such as straws, wheat straws and the like generated by agricultural production, the non-renewable and non-sustainable properties of steel, cement and plastics are very obvious, the application range of the current green building wallboard is more and more extensive, but the current green wallboard in the market still has the following problems:

1. the weight of most of the wallboards is very heavy, so that inconvenience is brought in the transportation process, and the light wallboards have no bearing capacity, so that the wallboards are deformed and damaged due to external influence, the long-time use of the wallboards is not facilitated, and a lot of replacement cost is increased;

2. the concatenation of two wallboards is concatenation such as glue mostly, and it is very inconvenient when dismantling, and glue is difficult to dispel for the wallboard can't continue the secondary use, and the in-process of concatenation needs the staff to splice earlier again gummed process also time-wasting relatively, is unfavorable for quick installation.

Aiming at the problems, the novel design is carried out on the basis of the original green wallboard.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a light wallboard for a green building, and aims to solve the problems that most of wallboards in the market proposed in the background technology are heavy, so that inconvenience is brought in the transportation process, the light wallboard has no bearing capacity, the wallboards are deformed and damaged due to external influence, the long-time use of the wallboards is not facilitated, a lot of replacement cost is increased, most of the two wallboards are spliced by glue and the like, the two wallboards are inconvenient to disassemble, the glue is difficult to remove, so that the wallboards cannot be used for the second time, the process of splicing by workers for splicing and gluing is time-wasting, and the rapid installation is not facilitated.

In order to achieve the purpose, the utility model provides the following technical scheme: the utility model provides a light weight wallboard for green building, includes wallboard top layer and fixed block, the inside bearing layer that is provided with in wallboard top layer, and the inside puigging that is provided with in bearing layer, the inside bearing bar that is provided with in bearing layer, and bearing bar one side is provided with the lug, the bearing bar intermediate junction has the dwang, and bearing bar one side is provided with concave block, the lug both sides are connected with tightens up the spring, and tighten up spring one side and be connected with the block, fixed block one side is connected with concave block, and concave block one side is connected with the connecting axle.

Preferably, the wallboard top layer is symmetric distribution about the puigging both sides, and puigging both sides symmetric distribution has the bearing layer to wallboard top layer and puigging integrated installation.

Preferably, the concave block and the bearing rod form a rotating structure through a connecting shaft, the concave block and the fixing block are connected in a clamping mode, the upper portion of the groove of the concave block is communicated, and the concave block is of a symmetrical structure relative to the transverse center line of the bearing layer.

Preferably, the connected mode of dwang and bearing rod is for rotating the connection, and the bearing rod is symmetrical structure about the horizontal central line of dwang to the dwang is block structure with bearing layer central point, the bearing rod is "X" type about the central point of dwang.

Preferably, the two sides of the convex block are symmetrically distributed with clamping blocks, the clamping blocks and the convex block form a telescopic structure through a tightening spring, and the convex block and the concave block are connected in a clamping manner.

Preferably, the fixed blocks are uniformly distributed around the bearing layer at equal intervals, the fixed blocks are connected with the concave blocks in a clamping manner, and the fixed blocks are connected with the convex blocks in a clamping manner.

Compared with the prior art, the utility model has the beneficial effects that: the light wall board for green buildings comprises a light wall board,

1. the wallboard is simple in structure and light in weight, the bearing layer is arranged between the surface layer of the wallboard and the sound insulation layer, the inner part of the wallboard is supported and protected, the wallboard is supported when being impacted by external force, the damage of the wallboard is prevented, the service life of the wallboard is prolonged conveniently, and the bearing rod in the bearing layer is of a detachable structure, so that batch transportation is facilitated, and transportation cost is saved conveniently;

2. the concave block and the convex block are arranged at the splicing position of the wallboard and spliced in a clamping mode, so that glue does not need to be used in the splicing process, the wallboard is easy to disassemble, quick installation of the wallboard is facilitated, and the wallboard can be used secondarily conveniently.

Drawings

FIG. 1 is a schematic top view of the present invention;

FIG. 2 is a schematic view of a snap-fit structure of a bump and a fixing block according to the present invention;

FIG. 3 is a schematic view of an upright structure of the bearing bar and the fixing block of the present invention;

FIG. 4 is a schematic perspective view of a concave block according to the present invention;

fig. 5 is a schematic front view of the rotating rod and the bearing rod of the present invention.

In the figure: 1. a wallboard surface layer; 2. a sound insulating layer; 3. a bearing layer; 4. a concave block; 5. rotating the rod; 6. a load-bearing bar; 7. a bump; 8. tightening the spring; 9. a clamping block; 10. a connecting shaft; 11. and (5) fixing blocks.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-3, a light wall panel for green buildings comprises a wall panel surface layer 1 and a fixing block 11, in order to install the wall panel, a bearing layer 3 is disposed inside the wall panel surface layer 1, a sound insulation layer 2 is disposed inside the bearing layer 3, a bearing rod 6 is disposed inside the bearing layer 3, a convex block 7 is disposed on one side of the bearing rod 6, a rotating rod 5 is connected in the middle of the bearing rod 6, a concave block 4 is disposed on one side of the bearing rod 6, the wall panel surface layer 1 is symmetrically distributed on two sides of the sound insulation layer 2, the bearing layer 3 is symmetrically distributed on two sides of the sound insulation layer 2, the wall panel surface layer 1 and the sound insulation layer 2 are integrally installed, the rotating rod 5 is rotatably connected with the bearing rod 6, the bearing rod 6 is symmetrically structured on a transverse central line of the rotating rod 5, the rotating rod 5 and a central point of the bearing layer 3 are engaged, the bearing rod 6 is in an X shape on the central point of the rotating rod 5, the fixing blocks 11 are uniformly distributed around the bearing layer 3 at equal intervals, the fixing blocks 11 are connected with the concave blocks 4 in a clamping manner, the fixing blocks 11 are connected with the convex blocks 7 in a clamping manner, firstly, the wallboard surface layer 1 is moved to a position required by a wallboard, then, the wallboard surface layer 1 is fixed at the position, then, the concave blocks 4 penetrate through the bearing layer 3, so that the rotating rod 5 is mutually clamped with a fixing structure at the central point of the bearing layer 3, then, the concave blocks 4 are lifted upwards, so that the concave blocks 4 are mutually clamped with the fixing blocks 11 above, then, the other concave blocks 4 are mutually clamped with the fixing blocks 11 below, and as above, the two convex blocks 7 are mutually clamped with the fixing blocks 11 at the other side in the same manner, at the moment, the concave blocks 4 and the convex blocks 7 drive the bearing rod 6 to rotate by taking the rotating rod 5 as the central point, the bearing rod 6 is in an X shape, the wallboard surface layer 1 is symmetrically distributed on two sides of the sound insulation layer 2, and 2 bilateral symmetry on puigging distribute has bearing layer 3, and wallboard top layer 1 and the installation of puigging 2 integration, be favorable to wallboard simple structure, the wallboard transportation of being convenient for, dwang 5 is connected for rotating with bearing bar 6's connected mode, and bearing bar 6 is symmetrical structure about the horizontal central line of dwang 5, and dwang 5 is the block structure with 3 central points on bearing layer, bearing bar 6 is the X type about the central point of dwang 5, be favorable to supporting the wallboard, prevent that the wallboard from warping because of external force.

Referring to fig. 1-5, in order to install the wall panel quickly, two sides of the convex block 7 are connected with tightening springs 8, one side of the tightening springs 8 is connected with a clamping block 9, one side of the fixed block 11 is connected with a concave block 4, one side of the concave block 4 is connected with a connecting shaft 10, the concave block 4 forms a rotating structure with the bearing rod 6 through the connecting shaft 10, the concave block 4 is connected with the fixed block 11 in a clamping way, the upper part of the groove of the concave block 4 is communicated, the concave block 4 is in a symmetrical structure with respect to the transverse center line of the bearing layer 3, the clamping blocks 9 are symmetrically distributed on two sides of the convex block 7, the clamping blocks 9 form a telescopic structure with the convex block 7 through the tightening springs 8, the convex block 7 is connected with the concave block 4 in a clamping way, when the concave block 4 and the convex block 7 are fixed with the fixed block 11, the other wall panel is fixed with the same as the above, and then the concave block 4 and the convex block 7 of the other wall panel are positioned at one side, then another wall board is pushed to enable the convex block 7 to enter the concave block 4, the clamping block 9 is extruded to be tightly attached to the convex block 7 in the entering process, then when the top of the convex block 7 enters the concave block 4, the tightening spring 8 rebounds to the clamping block 9 to fix the convex block 7 and the concave block 4 and prevent the convex block 7 and the concave block from being separated, meanwhile, when the two wall boards are tightly attached, the convex block 7 and the concave block 4 are retracted into the bearing layer 3, the bearing rod 6 is extruded at the moment, two ends of the bearing rod 6 are fixed above the convex block 7 and the concave block 4, when the wall boards need to be disassembled, one wall board is pressed, the other wall board is lifted, as the top of the concave block 4 is provided with a through slot, the convex block 7 ascends along the top of the concave block 4 at the moment, the clamping with the convex block 7 and the concave block 4 is removed, the disassembly of the wall boards is completed, the concave block 4 and the bearing rod 6 form a rotating structure through a connecting shaft 10, and the concave block 4 is connected with the fixed block 11 in a clamping manner, and the fluting top of concave block 4 link up, and concave block 4 is symmetrical structure about the horizontal central line of bearing layer 3, is favorable to removing the block of concave block 4 and lug 7 fast, is convenient for the dismantlement of wallboard, and lug 7 bilateral symmetry distributes has block 9, and block 9 constitutes extending structure through tightening up spring 8 and lug 7 to the connected mode of lug 7 and concave block 4 is the block connection, is favorable to the block compactness of lug 7 and concave block 4, is convenient for connect the wallboard.

The working principle is as follows: according to the figures 1-3, firstly, the wallboard surface layer 1 is moved to the position required by the wallboard, then the wallboard surface layer 1 is fixed at the position, then the concave block 4 penetrates through the bearing layer 3, so that the rotating rod 5 is mutually clamped with the fixing structure at the central point of the bearing layer 3, then the concave block 4 is lifted upwards, so that the concave block 4 is mutually clamped with the fixed block 11 above, then the other concave block 4 is mutually clamped with the fixed block 11 below, and as above, the two convex blocks 7 are mutually clamped with the fixed block 11 at the other side in the same way, at this time, the concave block 4 and the convex block 7 drive the bearing rod 6 to rotate by taking the rotating rod 5 as the central point, and the bearing rod 6 is in an X shape at the moment;

according to the figures 1-5, after the concave block 4 and the convex block 7 are fixed with the fixed block 11, another wallboard is fixed with the same, then the concave block 4 and the convex block 7 of another wallboard are positioned at one side, another wallboard is pushed, so that the convex block 7 enters the concave block 4, the clamping block 9 is extruded to be tightly attached to the convex block 7 in the entering process, then when the top of the convex block 7 enters the concave block 4, the clamping block 9 is rebounded by the tightening spring 8 to complete the fixation of the convex block 7 and the concave block 4 and prevent the convex block 7 from being separated, meanwhile, when the two wallboards are tightly attached, the convex block 7 and the concave block 4 are retracted into the bearing layer 3, the bearing rod 6 is extruded at the moment, so that the two ends of the bearing rod 6 are fixed above the convex block 7 and the concave block 4, when the wallboards need to be disassembled, one wallboard is pressed, the other wallboard is lifted, because the top of the concave block 4 is a through slot, at the moment, the convex block 7 rises along the top of the concave block 4, the engagement between the convex block 7 and the concave block 4 is released, and the disassembly of the wall board is completed, which is the working process of the whole device, and the content which is not described in detail in the specification belongs to the prior art which is well known by the person skilled in the art.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides a light wallboard for green building, includes wallboard top layer (1) and fixed block (11), its characterized in that: wallboard top layer (1) is inside to be provided with bearing layer (3), and inside puigging (2) that is provided with of bearing layer (3), inside bearing bar (6) that is provided with of bearing layer (3), and bearing bar (6) one side is provided with lug (7), bearing bar (6) intermediate junction has dwang (5), and is provided with concave block (4) on one side of bearing bar (6), lug (7) both sides are connected with and tighten up spring (8), and tighten up spring (8) one side and be connected with block (9), fixed block (11) one side is connected with concave block (4), and concave block (4) one side is connected with connecting axle (10).

2. A lightweight wall panel for green buildings as claimed in claim 1, wherein: wallboard top layer (1) is the symmetric distribution about puigging (2) both sides, and puigging (2) bilateral symmetry distributes has bearing layer (3) to wallboard top layer (1) and puigging (2) integrated into one piece are installed.

3. A lightweight wall panel for green buildings as claimed in claim 2, wherein: the concave block (4) and the bearing rod (6) form a rotating structure through the connecting shaft (10), the concave block (4) is connected with the fixing block (11) in a clamping mode, the upper portion of the groove of the concave block (4) is communicated, and the concave block (4) is of a symmetrical structure relative to the transverse center line of the bearing layer (3).

4. A lightweight wall panel for green buildings as claimed in claim 3, wherein: dwang (5) are connected for rotating with the connected mode of bearing bar (6), and bearing bar (6) are symmetrical structure about the horizontal central line of dwang (5) to dwang (5) are the block structure with bearing layer (3) central point, bearing bar (6) are "X" type about the central point of dwang (5).

5. A lightweight wall panel for green buildings as claimed in claim 2, wherein: the clamping blocks (9) are symmetrically distributed on two sides of the convex block (7), the clamping blocks (9) and the convex block (7) form a telescopic structure through a tightening spring (8), and the convex block (7) is connected with the concave block (4) in a clamping mode.

6. A lightweight wall panel for green buildings as claimed in claim 2, wherein: the fixed block (11) is evenly distributed around the bearing layer (3) in equal distance, the fixed block (11) is connected with the concave block (4) in a clamping manner, and the fixed block (11) is connected with the convex block (7) in a clamping manner.

Images